The content discusses the challenge of computing the exact optimal experimental design, which is a mixed-integer nonlinear programming problem that is typically NP-hard. The authors focus on improving the efficiency of the branch-and-bound (BnB) method, which is a widely used approach for solving such problems.
The key contributions are:
The authors propose a novel projected Newton framework, combined with a vertex exchange method, to efficiently solve the continuous relaxations within the BnB search tree. This framework offers strong convergence guarantees and significantly improves the efficiency of node evaluation compared to existing methods.
The authors develop an open-source Julia package called PNOD.jl that can be used to compute exact D-optimal and A-optimal experimental designs. The numerical experiments demonstrate the excellent efficiency of the proposed framework, showing that it can explore many more nodes within the BnB method compared to state-of-the-art methods.
The content first provides an overview of the BnB method and how it can be applied to the optimal experimental design problem. It then focuses on efficiently solving the continuous relaxations, which is a key component of the BnB method. The authors compare two approaches: the vertex exchange method and the projected Newton method combined with the vertex exchange method. The latter is shown to be significantly more efficient in practice.
Finally, the authors present extensive numerical experiments on A-optimal and D-optimal design problems, demonstrating the superior performance of the proposed framework compared to existing methods.
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by Ling Liang, ... kl. arxiv.org 09-30-2024
https://arxiv.org/pdf/2409.18392.pdfDybere Forespørgsler